KR20120028688A - Apparatus for separation and condensation of the mixture - Google Patents

Abstract

PURPOSE: An apparatus for separating and condensing mixed material is provided to automatically distribute a small amount of mixtures by forming a sample evaporation unit and a collection unit. CONSTITUTION: An apparatus for separating and condensing mixed material comprises a base unit(1), a sample evaporation unit(2), a collection unit, an actuating unit(5), and a control device. The sample evaporation unit is installed in the base unit, and stores and evaporates samples. Multiple collectors(4-2) of the collection unit are continuously aligned in a line. Materials evaporated in the sample evaporation unit successively pass through the collectors. In order to pass the collectors through the sample evaporation unit in order, the actuating unit moves the collection unit. The control device controls the sample evaporation unit to evaporate the sample, and controls the actuating unit to move the collection unit.

Description

Apparatus for separation and condensation of the mixture

The present invention relates to a mixture separation condensation apparatus.

Identifying the components of the mixed solution is of great importance both industrially and academically. In modern times, the chromatographic separation analysis method is the most widely used for the precise analysis of the components of complex mixed solutions. However, performing separation analysis using this method requires accumulated experience and skill.

Another mixed solution separation method is fractional distillation using boiling point differences of the components, and the conventional fractional distillation apparatus associated with it is widely used for separation-purification such as petroleum refining.

However, these conventional fractional distillation units are not suitable for separation and analysis of small samples because they are cumbersome to operate in combination with modern chemical instrumentation equipment and are designed and manufactured for the separation of large quantities of materials. There is a problem.

Meanwhile, other conventional techniques for separating and analyzing components using differences in boiling point and vaporization point of materials are found in fusion analysis techniques such as TG-MS and TG-IR, which combine thermogravimetry, mass spectrometry, and infrared spectroscopy. .

These methods measure the respective weight changes associated with the evaporation, vaporization, and pyrolysis processes of the sample, while simultaneously analyzing the gas content by directing the vapors and gases released in each process with mass spectrometers and infrared spectroscopy.

This method has the advantage of enabling on-line separation-analysis, but there is a problem that it is not suitable to analyze the separated gas (multiple) using multiple analytical methods because it analyzes the flowing gas.

In addition, there is a problem that requires a major change of the existing equipment in order to connect the individually produced thermogravimetric analyzer, mass spectrometer and infrared spectrometer.

The present invention has been made to solve the above problems, the mixture having a sample vaporizing unit suitable for vaporizing a small amount of sample and a collecting unit suitable for collecting a small amount of the mixture to enable automatic separation of the small amount of the mixture It is to provide a separate condensation device.

The present invention for achieving the above object, the base; A sample vaporization unit installed at the base and storing a sample and vaporizing the stored sample; A collection unit installed at the base and having a plurality of collectors arranged in series in a row to collect a sample, and having a plurality of collectors sequentially passing the material vaporized in the sample vaporization unit; A driving unit for moving the collection unit such that the collector of the collection unit passes the sample vaporization unit sequentially; And a control device for controlling the sample vaporization unit to vaporize the sample and controlling the driving unit to move the collection unit.

In addition, the present invention is characterized in that it further comprises a cooling unit for cooling the collection unit.

In addition, the present invention is characterized in that it further comprises a purging unit for maintaining the collection unit in a dry state.

In addition, the present invention is characterized in that it further comprises a temperature measuring unit for measuring the temperature of the sample vaporization unit.

In addition, the control device of the present invention is characterized in that for controlling the moving speed of the collection unit in proportion to the temperature change of the sample vaporization unit.

In addition, the sample vaporization unit of the present invention; A heater for heating the sample cell; And a cell holder installed at the base and for mounting the sample cell and the heater.

In addition, the collecting unit of the present invention includes a plurality of collectors formed to be continuously arranged in a row to collect a sample and a plurality of collectors provided in order to sequentially move to pass through the material vaporized in the sample vaporization unit ; And it characterized in that it comprises a support member for supporting the moving plate to be spaced apart from the base.

In addition, the present invention is characterized in that it further comprises an inductor having an opening formed to restrict the vaporized material to be attached only to a limited collector.

In addition, the interval of the opening of the induction machine of the present invention is characterized in that it is adjustable.

In addition, the collector of the present invention is characterized in that the plate shape.

In addition, the collector of the present invention is characterized in that the solid plate having a fine pattern of 0.1 ~ 100㎛ intervals.

In addition, the collector of the present invention is characterized in that the capillary is formed capillary array grid.

In addition, the control device of the present invention, the temperature controller for increasing the temperature of the sample vaporization unit in proportion to the set temperature increase rate; A driving controller for controlling the driving unit to move the collection speed in proportion to the temperature change amount of the sample vaporization part; And a central controller controlling the driving unit through the driving controller so that the moving speed of the collecting unit is proportional to the temperature change of the sample vaporizing unit.

Prior to this, the terms or words used in this specification and claims are not to be interpreted in a conventional and dictionary sense, and the inventors may appropriately define the concept of terms in order to best describe their own invention. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

According to the present invention as described above is provided with a sample vaporization unit suitable for vaporizing a small amount of sample and a collection unit suitable for collecting a small amount of sample can be automatically separated from the small amount of the mixture.

1 is a perspective view of a mixture separation condensation apparatus according to a first embodiment of the present invention.
2 is a cross-sectional view of the mixture separation condensation apparatus of FIG. 1.
3 is a plan view of the moving plate of FIG. 1.
4-8 are various embodiments of collectors.
9 is a configuration diagram of the control device of FIG. 1.
10 is a graph showing the temperature and the moving speed of the moving plate over time.
11 is a graph showing temperature over time and collector number accordingly.
12 is a perspective view of the mixture separation condensation apparatus according to the second embodiment of the present invention.
FIG. 13 is a cutaway view of the FIG. 12 mixture separation condensation apparatus. FIG.
14 is a plan view of the moving plate of FIG. 12.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components as possible, even if displayed on different drawings have the same number as possible. In addition, in describing the present invention, if it is determined that the detailed description of the related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a mixture separation condensation apparatus according to a first embodiment of the present invention, FIG. 2 is a cross-sectional view of FIG. 1, and FIG. 3 is a plan view of the moving plate of FIG. 1.

Referring to the drawings, the mixture separation condensation apparatus according to the first embodiment of the present invention, the base 1, the sample vaporization unit 2, the temperature measuring unit 3, the collecting unit 4, the drive unit (5) And the cooling part 6 is provided.

Here, the base part 1 is formed in plate shape, and the sample vaporization part 2, the drive part 5, etc. are provided. In the drawings, the base 1 is formed of a circular plate, but is not limited thereto.

The sample vaporizing unit 2 stores a sample, and is a device for heating and vaporizing a stored sample. The sample vaporizing unit 2 includes a sample cell 2-1 containing a sample and a heater for heating the sample cell 2-1. (2-2) and fixing for fixing the cell holder (2-3) and the cell holder (2-3) to the base (1) for mounting the sample cell (2-1) and the heater (2-2) Means 2-4 are provided.

The sample stored in the sample cell 2-1 of the sample vaporization unit 2 may be various liquid mixtures, liquid-solid mixtures, solid mixtures, or solids having foreign substances on the surface and inside.

In addition, the sample cell 2-1 of the sample vaporizing unit 2 preferably has a structure suitable for storing the sample in a cylindrical shape with an opening formed on one surface thereof, and transfers the heat of the heater 2-2 to the sample well. It is preferable to use a substance. In the sample cell 2-1, it is preferable that a part of the cell holder 2-3 has an opening formed therein.

Next, the heater 2-2 of the sample vaporization unit 2 is for heating the sample cell 2-1, and is formed to surround the sample cell 2-1 to cover the sample cell 2-1. It is preferable to use a thermoelectric element such that) is heated uniformly throughout. Of course, the oven 2-2 of the sample vaporization part 2 may use the oven etc. which can heat the whole.

The cell holder (2-3) of the sample vaporization unit (2) is for mounting the sample cell (2-1) and the heater (2-2), the sample cell (2-1) and the heater (2- 2) It is provided with the cavity formed so that it is suitable for accommodating, and the sample cell 2-1 and the heater 2-2 can be mounted.

The shape of the cell holder 2-3 is illustrated as a cylindrical shape, but is not limited thereto. Various shapes may be used.

Fixing means 2-4 are used to attach this cell holder 2-3 to the base 1, and the fixing means 2-4 may preferably be double-sided adhesive. Alternatively, a fastening pin or the like may be used that protrudes from the bottom of the base 1 upwardly with the fixing means 2-4 so that the cell holder 2-3 is fixed to the base 1.

On the other hand, the temperature measuring unit 3 is provided inside or around the sample cell 2-1 of the sample vaporizing unit 2, but the temperature measuring unit 3 provided includes the sample cell 2-1. Measure and transmit the internal or ambient temperature.

In this case, various types such as a platinum resistance temperature sensor, a thermocouple, a pyrometer, and an IC thermometer may be used as the temperature measuring unit 3 without limitation.

Next, the collecting unit 4 is a plurality of collectors 4-2 formed so that the moving plate 4-1 and the substance to be continuously arranged and vaporized in one line on one surface of the moving plate 4-1 can be attached. And the induction machine 4-3 and the base 1 having the opening 4-4 for restricting the vaporized material to be attached only to the limited collector 4-2, and the movable plate 4 -1) is provided with a supporting member 4-6 which is supported so as to be spaced apart from the base 1.

In the configuration of the collecting unit 4, the movable plate 4-1 is formed in a disc shape and preferably rotates about an axis. Of course, the moving plate 4-1 may be formed as a rectangular plate to form a linear motion in the long side direction.

The moving plate 4-1 may be made of various metals or polymers, and copper having high thermal conductivity that can be easily cooled by the cooling unit 6 is preferable.

In this movable plate 4-1, grooves 4-7 are formed in a track shape around a center as shown in FIG. 3, which is a plan view, and a plurality of collectors 4-2 are formed in the grooves 4-7 formed. Are continuously attached in a row.

As such, the collector 4-2 attached to the movable plate 4-1 may be, for example, a smooth solid plate 4-2A such as a glass plate, as shown in FIG. 4, or illustrated in FIG. 5 and FIG. 6. As shown in the cross-sectional view, a solid plate 4-2B having a fine pattern 4-2BA with a spacing of 0.1 to 100 μm in order to increase collection efficiency by using a capillary phenomenon is shown in FIG. A capillary array 4-2C in which the short capillary tube 4-2CA shown in cross section is densely lattice can be used.

The material of such collector 4-2 may be metal, glass, semiconductor, ceramic.

Next, the inductor 4-3 is an opening 4-4 that directs the vaporized material to the collector 4-2 without loss so that the vaporized material can be attached to the collector 4-2 well. It may be formed in a plate shape including).

In the inductor 4-3, the opening 4-4 may be formed in a funnel shape in which the diameter thereof becomes smaller toward the collector 4-2.

In addition, the inductor 4-3 may further include a spacer 4-5 between the collector 4-2 and the spacer 4-4 so as to be spaced apart from the collector 4-2. The height can be adjusted to move the distance apart or close.

In addition, the opening 4-4 of the inductor 4-3 may allow the gap to increase or decrease as necessary. In this way, if the size of the opening 4-4 formed in the inductor 4-3 or the separation distance from the collector 4-2 can be adjusted, the size of the opening 4-4 depends on the amount of the vaporized material. The distance from the collector 4-2 can be adjusted to allow for larger amounts to be easily attached to the collector 4-2.

Next, the supporting member 4-6 is to be spaced apart from the base 1 by supporting the moving plate 4-1, and may be formed as a hollow cylinder. The driving part 5 is mounted in the support member 4-6. The support member 4-6 is provided to support the moving plate 4-1 and to mount the driving unit 5, but the driving unit 5 supports the moving plate 4-1 without providing it. It may be to replace the role of the support member (4-6).

On the other hand, the driving unit 5 is for moving the moving plate 4-1, a piezoelectric motor, a stepping motor, or the like may be used. When the movable plate 4-1 is configured to be rotatable in a disk shape, the driving unit 5 rotates the movable plate 4-1.

In addition, the cooling unit 6 is for cooling the collector 4-2 to condense the substance attached to the collector 4-2, and a heat exchanger or a Peltier cooler connected to the refrigerant circulation device may be used.

 The automatic mixture separation condensation apparatus according to the first embodiment of the present invention thus constructed is driven and controlled by a control device, and FIG. 9 shows a detailed configuration of such a control device.

9, the control device 7 used in the present invention includes a heating power supply 7-1, a temperature controller 7-2, a driving power supply 7-3, and a driving controller 7-. 4) and a central controller 7-5.

The heating power supply 7-1 is a device for supplying power to the heater 2-2. Then, the temperature controller 7-2 properly controls the power supplied to the heater 2-2 so that the temperature of the sample cell 2-1 maintains the desired temperature.

The driving power supply 7-3 supplies power to the driving unit 5 so that the driving unit 5 can move the moving plate.

The drive controller 7-4 controls the moving speed of the moving plate moved by the drive unit 5 by controlling the power supplied to the drive unit 5 by controlling the drive power supply 7-3.

Next, the central controller 7-5 controls so that the moving speed of the moving plate moved by the driving unit 5 is proportional to the temperature with reference to the temperature measured from the temperature measuring unit 3.

Referring to FIG. 10, which shows the rotational speed of the moving plate according to temperature, if the temperature is increased (see graph A), the moving speed of the moving plate is proportional to the temperature gradient, and in the section where there is no temperature change, the moving plate You can keep the speed constant as zero (see graph B-1) or as a dotted line (see graph B-2).

In this case, as shown in FIG. 11, which shows the collector number remaining to be exposed to the opening 4-4 of the inductor 4-3 according to the temperature, the corresponding collector in the section where there is no temperature change of the sample cell is shown. A large amount of material is attached to (collector number 3) and collected.

 Looking at the operation of the mixture separation condensation apparatus according to the first embodiment of the present invention configured as described above are as follows.

First, a sample is prepared and put into the sample cell 2-1 with the heater 2-2, and then the sample cell 2-1 is mounted on the cell holder 2-3.

And the temperature of the inside and surroundings of the sample cell 2-1 is measured using the temperature measuring part 3 which is around the sample cell 2-1.

As such, when the temperature of the sample cell 2-1 is known, the set temperature increase rate V _s and the final temperature T _f are input to the central controller 7-5 accordingly. Here, the set elevated temperature means the amount of change in the temperature of the cell holder per unit time. The final temperature is the highest temperature at which heating ends. This set temperature increase rate and final temperature may be directly input to the temperature controller 7-2.

 Also, a proportional constant z for adjusting the speed of the moving plate is input to the central controller 7-5. Of course, it is possible to directly input the proportional constant for adjusting the speed of the moving plate to the drive controller 7-4 without going through the central controller 7-5.

When the proportional constant is input to the central controller 7-5, the central controller 7-5 controls the drive controller 7-4 so that the driving unit 5 moves the moving plate with respect to the measured heating rate V _r . The moving plate may be controlled to move in proportion to the proportional constant.

That is, the central controller 7-5 may control the moving plate to move at the moving speed represented by Equation 1 below.

(Equation 1)

V _m = z * V _r

Here, V _m is the moving speed of the moving plate, z is the proportional constant, and V _r is the measured heating temperature.

Here, the measured temperature increase rate means the amount of change per unit time of the temperature measured by the temperature measuring unit 3.

In this way, when the set temperature increase rate, the final speed, and the proportional constant for adjusting the speed of the moving plate are input to the central controller 7-5, the temperature controller 7-2, or the drive controller 7-4, the central controller 7-5 is input. Or the temperature controller 7-2 controls the heating power supply 7-1 so that power is supplied to the heater 2-2 so that the temperature of the sample cell 2-1 rises in proportion to the set heating rate. Allow the sample cell 2-1 to heat up.

At the same time, when the temperature measuring unit 3 measures the temperature of the sample cell and transmits the temperature to the central controller 7-5, the central controller 7-5 is a speed proportional to the actual temperature rise rate of the sample cell by a proportional constant. The drive controller 7-4 is controlled to rotate the moving plate so that the drive power supply 7-3 supplies the appropriate power to the drive unit 5.

By this process, the moving plate rotates at a speed proportional to the measured temperature increase rate and collects the vaporized material from the sample cell 2-1.

Of course, during this process, the cooling unit 6 cools the collector 4-2 to be maintained at a temperature lower than room temperature.

Meanwhile, the moving speed V _m , which is a fixed value, may be input to the central controller 7-5, rather than a proportional constant for adjusting the speed of the moving plate. In this case, the central controller 7-5 moves (or rotates) the moving plate at a constant speed regardless of the temperature of the sample cell 2-1 according to the moving speed V _m of the moving plate.

12 is a perspective view of the mixture separation condensation apparatus according to the second embodiment of the present invention, FIG. 13 is a cross-sectional view of FIG. 12, and FIG. 14 is a plan view of the moving plate of FIG. 12.

The difference between the mixture separation condensation apparatus according to the second embodiment of the present invention and the mixture separation condensation apparatus according to the first embodiment is that two sample vaporizers 2 and 2 'are provided instead of one ( Accordingly, two sample cells are also referred to as 2-1 and 2-1 ', two heaters are referred to as 2-2 and 2-2', and the cell holder is also referred to as 2-3 and 2-3 '. And two fixing means, 2-4 and 2-4 '.

Of course, there are also two temperature measuring units, 3 and 3 '. Accordingly, the collecting section 4 has another collector 4-2 'row in addition to one collector 4-2 (the inductor also has two candidates 4-3 and 4-3'). The number of openings is also 2 to 4-4 and 4-4 ', and the number of spacers is also 2 to 4-5 and 4-5').

Thus, if two sample vaporizers 2, 2 'are provided and thus two collectors 4-2, 4-2' are provided, two collectors 4-2, 4-2 are driven in one drive. ') Can be collected through heat, doubling the collection material.

In some cases, different mixtures may be fractionally distilled at the same time as long as other mixtures are stored and vaporized in the sample vaporization sections 2 and 2 '.

In addition, in the second embodiment, a purging part 8 is further provided to operate the drying plate or to continuously purge the moving plate using dry nitrogen gas to prevent unwanted condensation of moisture in the air. Keep it dry.

Although the present invention has been described above, this is only one embodiment, and it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the present invention. . However, it will be confirmed through the claims that such changes and modifications fall within the scope of the present invention.

1: Base 2, 2 ': Sample Vaporization Section
2-1, 2-1 ': sample cell 2-2, 2-2': heater
2-3, 2-3 ': Cell holder 2-4, 2-4': Fixing means
3, 3 ': temperature measuring section 4: collecting section
4-1: Moving plate 4-2, 4-2 ': Collector
4-3, 4-3 ': Inductor 4-4, 4-4': Opening
4-5, 4-5 ': spacer 4-6: support member
4-7: Groove 5: Drive Section
6: cooling unit 7: control device
7-1: heating power supply 7-2: temperature controller
7-3: drive power supply 7-4: drive controller
7-5: central controller 8: purging part

Claims (13)

Base;
A sample vaporizer installed at the base to store a sample and vaporize the stored sample;
A collection unit installed at the base and having a plurality of collectors arranged in series in a row to collect a sample, and having a plurality of collectors sequentially passing the material vaporized in the sample vaporization unit;
A driving unit for moving the collection unit such that the collector of the collection unit passes the sample vaporization unit sequentially; And
And a control device for controlling the sample vaporization unit to vaporize the sample and controlling the driving unit to move the collection unit.
The method according to claim 1,
Mixture separation condensation device further comprises a cooling unit for cooling the collection.
The method according to claim 1,
Mixing separation condensation device further comprises a purge for maintaining the collection in the dry state.
The method according to claim 1,
Mixture separation condensation device further comprising a temperature measuring unit for measuring the temperature of the sample vaporization unit.
The method according to claim 1,
The control device is a mixture separation condensation apparatus, characterized in that for controlling the moving speed of the collector proportional to the amount of temperature change of the sample vaporization unit.
The method according to claim 1,
The sample vaporization unit,
A sample cell for storing a sample;
A heater for heating the sample cell; And
A mixture separation condensation device installed at the base and including a cell holder for mounting a sample cell and a heater.
The method according to claim 1,
The collection unit,
A moving plate including a plurality of collectors formed to be continuously arranged in a row to collect a sample, and a plurality of collectors sequentially moving to pass a material vaporized in the sample vaporization unit; And
And a support member supporting the moving plate to be spaced apart from the base.
The method according to claim 7,
A mixture separation condensation device further comprising an inductor having an opening for restricting the vaporized material to be attached to only a limited collector.
The method according to claim 8,
And the spacing of the openings of the inductor is adjustable.
The method according to claim 1,
Mixture separation condensation device, characterized in that the collector is plate-shaped.
The method according to claim 1,
The collector is a mixture separation condensation device, characterized in that the solid plate having a fine pattern of 0.1 ~ 100㎛ intervals.
The method according to claim 1,
And the collector is a capillary array in which the capillaries are formed lattice.
The method according to claim 1,
The control device,
A temperature controller that increases the temperature of the sample vaporization unit in proportion to a set temperature increase rate;
A driving controller for controlling the driving unit to move the collection speed in proportion to the temperature change amount of the sample vaporization part; And
And a central controller controlling the driving unit through the driving controller so that the moving speed of the collecting unit is proportional to the temperature change amount of the sample vaporizing unit.

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